Percolation of strongly correlated Gaussian fields I. Decay of subcritical connection probabilities

Abstract

We study the decay of connectivity of the subcritical excursion sets of a class of strongly correlated Gaussian fields. Our main result shows that, for smooth isotropic Gaussian fields whose covariance kernel K(x) is regularly varying at infinity with index α ∈ [0, 1), the probability that \f \, < c, connects the origin to distance R decays sub-exponentially in R at log-asymptotic rate cα (c-)2 / K(R) for an explicit cα > 0. If α = 1 and ∫0∞ K(x) dx = ∞ then the log-asymptotic rate is c1 (c-)2 R (∫0R K(x) dx)-1, and if α > 1 the decay is exponential. Our findings extend recent results on the Gaussian free field (GFF) on Zd, d 3, and can be interpreted as showing that the subcritical behaviour of the GFF is universal among fields with covariance K(x) c|x|d-2. Our result is also evidence in support of physicists' predictions that the correlation length exponent is = 2/α if α 1, and in d=2 we establish rigorously that 2/α. More generally, our approach opens the door to the large deviation analysis of a wide variety of percolation events for smooth Gaussian fields. This is the first in a series of two papers studying subcritical level-set percolation of strongly correlated Gaussian fields, which can be read independently.